System and method for recycling and recapture of bio-based plastics

ABSTRACT

A method for reclaiming bio-based plastic material is disclosed, including providing a bio-based plastic article, the article including an identifier, determining article content information from or via the identifier, and recycling the article based on article content information. Further, a system for reclaiming bio-based plastic material is disclosed, including an apparatus or device configured to obtain or determine a bio-based material content associated with a plastic article, and an apparatus or device configured to sort the plastic article based upon the bio-based material content of the plastic article. A bio-based plastic article comprising recycled bio-based material is also disclosed.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a continuation application of U.S. patentapplication Ser. No. 15/166,017, filed May 26, 2016, now U.S. Pat. No.10,744,680, issued Aug. 18, 2020, which is a divisional of U.S. patentapplication Ser. No. 13/796,481, filed Mar. 12, 2013, now U.S. Pat. No.9,353,237, issued May 31, 2016, which application claims the benefit ofpriority to U.S. Provisional Application No. 61/751,488, filed Jan. 11,2013, the entire disclosures of which are incorporated herein byreference.

TECHNICAL FIELD

The present invention relates to a system and method for recycling andrecapture of bio-based plastics, articles processed through such asystem and method, and article produced from such system and method.

BACKGROUND

Plastics, such as PET, PE, and PP, are commonly used in connection withthe manufacture of packaging articles, such as bottles and containers.However, as used herein, “article” shall not be limited to packagingarticles. The term “PET” refers to polyethylene terephthalate, and mayinclude its copolymers and combinations. The term “PE” refers topolyethylene, and may include high density polyethylene (“HDPE”), lowdensity polyethylene (“LDPE”), and its copolymers and combinations. Theterm “PP” refers to polypropylene, and may include its copolymers andcombinations. Plastic material, such as PET, can be provided in a numberof forms, including flakes and pellets.

PET that is comprised of petrochemical-derived raw materials, orpetroleum-based PET, is commonly used to manufacture a number ofcommercial articles. The cost of petroleum-based PET is, however,closely related to the cost of petroleum. Moreover, as petrochemicalstake hundreds of thousands of years to form naturally,petrochemical-derived products are considered to be non-renewable.

Methods for making bio-based plastics, such as bio-based PET packaging,have been disclosed in the art. The term “bio-based” generally refers tothe biogenic carbon content of an article, which can be represented as afraction weight (mass) or percent weight (mass) of the total organiccarbon in the article per the ASTM D6866 standard. This standard methodcan be used to determine precise percentages of a solid, liquid, or gasthat came from renewable sources by measuring the material's carbon-14(C¹⁴) content. Since C¹⁴ decays at a predictable rate over time (havingan approximately 5,000 year half-life) and becomes stable C¹⁴ isotope,fossil fuels generally do not contain C¹⁴ content due to their age.Thus, the presence of C¹⁴ versus C¹² in a material can be used tosignify/quantify bio-based carbon content. The term “bio-based” can beused to indicate the inclusion of a component that is fully or partiallyderived from at least one bio-based material, i.e., an organic materialin which the associated carbon comes from non-fossil biological sources.

Consumer demand for bio-based plastics, including but not limited toPET, has been on the rise, increasing the need for more productive andefficient means of meeting such demand. Further, many governments,corporations and other organizations have given high priority todeveloping, finding, subsidizing and using more bio-based products,including plastics. For example, and without limitation, the UnitedStates Department of Agriculture has a BioPreferred program that steerscontractors towards using more bio-based materials. Average consumersare also becoming more aware of and predisposed to purchasing bio-basedproducts. The sophistication has grown to the point where consumers may,prior to making a purchase, inquire as to the actual bio-based contentpercentage, recycled content percentage, and/or material types andsources.

For plastic articles, such as containers, including those made from PET,an object can be to economically maximize the bio-based content of thearticle. Some conventional articles include up to about 30% bio-basedcontent. However, conventional PET containers are not more than one-halfbio-based, and commercially available PET containers are not 100%bio-based. Conventional containers with a portion of bio-based content,such as those marketed under the PLANT BOTTLE™ trademark, may employ PETresin having one building block derived from petroleum, and anotherbuilding block derived from bio-based sources. Specifically, the maincomponents in manufacturing PET via polymerization include terephthalicacid/ester (TA) and ethylene glycol (EG). While the ratios may varyslightly, a typical PET manufacturing process might use about 68.75% TAand about 31.25% EG on a mass basis. Terephthalic acid has eight carbonatoms per molecule, while ethylene glycol has two. The resultingmolecule of PET may include 10 total carbon atoms derived from acombination of TA and EG.

Certain bio-based feedstock, including but not limited to sugar cane,sugar beets, or other forms of natural sugar, can be used to producebio-based EG. The typical process includes converting the feedstock(e.g., via hydro-cracking) into ethylene, adding oxygen to form ethyleneoxide, and then adding water to form EG. This process for bio-based EGis similar to that of petrol-based EG, differing primarily in the choiceof feedstock and process for converting the feedstock into ethylene.Although generally more expensive and less plentiful than petrol-basedEG, bio-based EG is commercially available and is used in someconventional PET resins, for example, those marketed under the PLANTBOTTLE™ name. These resins are said to reach up to 30% bio-basedcontent, derived solely from the bio-based EG component.

A conventional petrol-based process for manufacturing terephthalic acidcomprises refining naphtha from crude oil and reforming to paraxylene(pX). The paraxylene is mixed with a solvent (typically acetic acid),catalyst, and promoter and oxidized into crude TA, which may be furtherrefined into purified TA (PTA). Some methods for manufacturing bio-basedTA, including those described in U.S. patent application Ser. No.12/577,480 (Patent Publication No. 2010/0028512), have been proposed.

Further, and without limitation, bio-based polyethylene may bemanufactured from 100% bio-based feedstock. A currently availableprocess comprises processing sugar cane or any other form of naturalsugar (such as sucrose), fermenting and distilling into ethanol,dehydrating to form ethylene, and then polymerizing to formpolyethylene. Such a process can be employed in connection with multipleforms of polyethylene including, without limitation, high densitypolyethylene (HDPE), linear low density polyethylene (LLDPE), amongothers. A process associated with forming polypropylene (PP) may be verysimilar to that associated with forming polyethylene. After formingethylene, though, the ethylene can be converted to propylene via adimerization or metathesis process. The propylene monomer may then beconverted to polypropylene.

In the pursuit of more eco-friendly packaging, bio-based products,including plastics, are gaining acceptance as potential alternatives topetrol-based products. While certain bio-based plastic materials areknown, and may be currently sold in the market, a challenge has been tocreate an effective means for identifying and recapturing such materialin a recycling system.

SUMMARY

A method for reclaiming bio-based plastic material is disclosed,including providing a bio-based plastic article, the article includingan identifier, determining article content information from or via theidentifier, and recycling the article based on article contentinformation. Further, a system for reclaiming bio-based plastic materialis disclosed, including an apparatus or device configured to obtain ordetermine a bio-based material content associated with a plasticarticle, and an apparatus or device configured to sort the plasticarticle based upon the bio-based material content of the plasticarticle. A bio-based plastic article comprising recycled bio-basedmaterial is also disclosed.

BRIEF DESCRIPTION OF THE DRAWINGS

Embodiments of the disclosure will now be described, by way of example,with reference to the accompanying drawings, wherein:

FIG. 1A is a side elevation view of an embodiment of an article, morespecifically a plastic container, including a bio-based identifier;

FIG. 1B is a bottom view of the article as shown in FIG. 1A, morespecifically a plastic container (base view), including a bio-basedidentifier;

FIG. 2A is a depiction of an embodiment of an article, more specificallya plastic package, including a bio-based identifier;

FIG. 2B is a depiction of an embodiment of another article, morespecifically, a plastic bottle, including a bio-based identifier;

FIG. 3A is a graphical representation of an embodiment of a system andapparatus for use in identifying a bio-based identifier on an article;

FIG. 3B is graphical representation of another embodiment of a systemand apparatus for use in identifying a bio-based identifier on anarticle;

FIG. 4A is a flow chart generally illustrating an embodiment of aprocess for identifying and recycling bio-based articles;

FIG. 4B is a flow chart generally illustrating another embodiment of aprocess for identifying and recycling bio-based articles; and

FIG. 4C is a flow chart generally illustrating yet another embodiment ofa process of identifying and recycling bio-based articles.

DETAILED DESCRIPTION

Reference will now be made in detail to embodiments of the presentdisclosure, examples of which are described herein and illustrated inthe accompanying drawings. While the invention will be described inconjunction with embodiments, it will be understood that they are notintended to limit the invention to these embodiments. On the contrary,the invention is intended to cover alternatives, modifications andequivalents, which may be included within the spirit and scope of theinvention as defined by the appended claims.

FIGS. 1A, 2A, and 2B generally illustrate embodiments of articles 10,20, and 22, respectively. Such articles may, as generally illustrated,comprise a plastic container (see, e.g., bottle generally illustrated inFIG. 2B) or plastic package (see, e.g., package generally illustrated inFIG. 2A) that include a bio-based identifier 30, such as disclosedherein.

FIGS. 3A and 3B generally illustrate embodiments of systems that may beused in connection with the disclosure. As generally depicted in FIG.3A, a device 40 may be used to acquire and/or identify an identifier 30from an article 10. The device may comprise, without limitation, apermanent or a portable electronic device that is capable of scanning,reading, or otherwise acquiring or identifying an identifier (such asfurther described herein). Examples such devices include, withoutlimitation, machine vision apparatus, hand-held scanning devices, andsmart phones. Additionally, as generally shown in FIG. 3A, a user mayvisually identify a given identifier associated with an article 10.

In a method for identifying and reclaiming bio-based plastic material,an identifier can be included with, part of, or incorporated into thematerial or article. In an embodiment, a bio-based plastic resin mayinclude an “identifier,” for example, one or more additives, that canaid in distinguishing such containers from petrol-based containers. Theinclusion of one or more identifiers can aid in the recycling process,and can be included in a manner that does not compromise or adverselyeffect intended commercial sale or use.

For example, without limitation, a colorant or dye (e.g., anultra-violet dye) may be included in the resin master batch at a smallpercentage or let-down ratio. The resin master batch can then be used inconnection with the production of plastic containers. The identifier(s)can be comprised or configured such that the identifier(s) isunobtrusive and, if desired, may not be generally visible/perceptible tothe human eye absent special equipment.

FIGS. 4A, 4B, and 4C generally illustrate embodiments of a process foridentifying and recycling bio-based articles.

With the embodiment of the process outlined in FIG. 4A, a resin for abio-based article (such as a container or package) is provided (step100). An identifier is added to the resin (step 110). The resin is thenconverted or otherwise processed to form an article, such as a containeror package (step 120). After the article (e.g., product) has been used(e.g., commercially), the product/article is received at a recyclinglocation or facility (step 130). An identification device or system(which could involve a user's visual identification) can then be used toidentify bio-based articles (e.g., articles meeting some bio-basedcriteria) (step 140). The process can then selectively recycle articlesthat meet a criteria (such as bio-based articles or certain select typesof bio-based articles) (step 150). The recycling can then result in theprovision or collection of recycled material, for example and withoutlimitation, recycled material that is bio-based (step 160).

With the embodiment of the process outlined in FIG. 4B, a bio-basedarticle is provided (step 200). An identifier is added to the article(step 210). The article is provided or otherwise received at a recyclinglocation or facility (step 220). An identification device or system(which could involve a user's visual identification) can then be used toidentify bio-based articles (e.g., articles meeting some bio-basedcriteria) (step 230). The process can then selectively recycle articlesthat meet a criteria (such as bio-based articles or certain select typesof bio-based articles) (step 240). The recycling can then result in theprovision or collection of recycled material, for example and withoutlimitation, recycled material that is bio-based (step 250).

In accordance with some embodiments of the disclosure, a custom blend ofPCR material that includes bio-based content can be provided. Suchcustom blend(s) with bio-based content may be based upon the bio-basedcontent of the associated feedstock or input into the process (e.g.,bales of post-consumer materials) along with the identification processutilized. The custom blend may optionally include both bio-based andpetrol-based materials at ratios that may be specified or optionallyselected by the processor.

With the embodiment of the process outlined in FIG. 4C, a bio-basedarticle is provided (step 300). The article is identified using anidentifier associated with the article (step 310). The identificationmay be accomplished, for example and without limitation, via a device orsystem (which could involve a user's visual identification) and mayidentify bio-based articles (e.g., articles meeting some bio-basedcriteria). The process can then selectively recycle articles that meet acriteria (such as bio-based articles or certain select types ofbio-based articles) (step 320). The recycling can then result in theprovision or collection of recycled material, for example and withoutlimitation, recycled material that is bio-based (step 250). In anembodiment, when containers with an identifier are received andprocessed for recycling (e.g., at a recycling facility), appropriateequipment, which may include, without limitation, scanners, infraredsensors, or cameras, may be used to identify containers that have anidentifier (e.g., colorant or dye). In an embodiment, a colorant or dyecan be included that is only visible via infrared detection.Additionally, with embodiments, various individual/specific identifiers(e.g., colorants or dyes) may be distinguishable from each other. Forexample and without limitation, different identifiers may be used to aidin the separation of bio-based containers that are 30% bio-based fromother containers that, for instance, are 100% bio-based, or may be usedto separate containers that are bio-based from those that arepetrol-based containers.

With other embodiments, the identifier used with bio-based resins (andarticles produced therefrom) may include a chemical tracer(s) that areadded to or included with a bio-based resin. During the production of aplastic resin, such as PET or PE, the manufacturer may include certain“tracers” that serve to distinguish resin produced by the manufacturerfrom similar resins produced by others. These tracers may be compounds(such as organic chemical(s)) added at minute levels, e.g., in thesingle parts per billion or less range. The tracer is preferably acompound not normally present from the standard polymerization process,but, at such small levels, the tracer will not negatively or adverselyaffect the resulting polymer's suitability with respect to recyclabilityor functionality. The tracers may be optionally added during the meltpolymerization phase or the solid state polymerization stage. Using atracer, molecular and/or chemical testing of resin batches could be usedto determine the origin, identity or provenance. While not required,tracers may optionally be include in embodiments to identify bio-basedarticles and selectively recover them within a recycling process.

In embodiments, bio-based resins (and articles produced therefrom) mayinclude the inclusion or placement of a distinguishing/visible mark onthe article (such as a container) that designates the article as“bio-based.” There are current industry accepted standard markingpractices for recyclability that are based on the plastic content of anarticle. For example, a PET container marked with a “1,” is suitable fora PET recycling process. Some extruded PET copolymers, while includingPET, are marked with a “7” or “Other,” may not be suitable for recyclingwith a standard PET process. HDPE containers marked with a “2” aresuitable for a HDPE recycling process, while PP containers marked with a“5” are suitable for a PP recycling process.

The disclosed system can utilize separate or additional marking todistinguish bio-based articles and, if desired, create a separaterecycling stream through a new code, and/or use an existing stream,while allowing the recycling facility to better identify and control thebio-based content in the PCR resin that it handles or produces. Forexample, in an embodiment, a designation/mark such as “BIO” or “B” maybe included with or in place of a recycling number. For instance, abio-based PET container can be marked as “1-B” or “1-BIO” or the like. Asymbol (e.g., a leaf) could also be used. Such markings and/or symbolscan be configured to be visible throughout the commercial life of theproduct, and can add to the marketability of the product. A recyclingfacility can then use a means for reading the identifier, including butnot limited to a recycle code, such as scanner, vision system, sortingmeans, human eyesight, or others.

In one embodiment, the identifier may comprise a marker, which mayinclude without limitation one or more UV dyes, colorants, chemicaltraces, organic additives, tints, others, or a mixture thereof. As usedherein, a “marker” is a compound that may be added, at optional let-downratios, to the resin at the production site, be it a blow molding,injection molding, extrusion molding, or other operation. The marker maygive a distinctive visual cue to a person and/or vision system employedat a recycling center, thereby readily conveying bio-based contentinformation. Further, the marker may give added benefits, includingwithout limitation reduction of article haze, added clarity, barrierproperties, material scavenging, and more.

For purposes of this disclosure, the term “identifier” refers to anelement, of structural or physical nature, of an article that isconfigured to disclose information regarding the bio-based content ofsaid article to a recycling process, system, method or user. Anidentifier may comprise a feature of or be associated with an embodimentdisclosed herein, but it is not intended to be limited to such.

Another aspect of the disclosure involves the manufacture of bio-basedplastic containers that incorporate at least a portion of recycledbio-based material. Such recycled content can come from post-consumer(PCR) or post-industrial (PIR) sources. For the purposes of thisdisclosure, “PCR” will be used to generally refer to recycled plastics,regardless of the source. Embodiments envision the use of a means foridentifying, segregating, and collecting bio-based plastic containersafter the containers have entered the commercial market to make thecollection of bio-based PCR resins for new containers reliable andcommercially feasible. Thus, while using virgin bio-based resin forcontainers (whether conventional-type “up to 30%” bio-based containersor even 100% bio-based containers) is generally “eco-friendly,” it couldbe more so with the incorporation of recycled bio-based materials.

Different combinations of plastic materials for the manufacture ofplastic containers is envisioned and described in connection with thenon-limiting examples identified in the table below.

Virgin PCR “up PCR PCR Virgin “up to Virgin PCR to 30% 100% CustomPetrol- 30% Bio- 100% Petrol- Bio- Bio- Blend Example based based”Bio-based based based” based Bio-based 1 0% 100%  0% 0% 0% 0% 0% 2 0% 0%100%  0% 0% 0% 0% 3 0% 25%  0% 75%  0% 0% 0% 4 90%  0% 0% 10%  0% 0% 0%5 90%  0% 0% 0% 10%  0% 0% 6 0% 90%  0% 0% 10%  0% 0% 7 90%  0% 0% 0% 0%0% 10% 

Example 1 might apply to a container such as that generally described inU.S. Patent Application Publication No. 2009/0246430, i.e., an “up to30% bio-based container.” Example 2 might apply to a container of thetype proposed in U.S. Patent Application Publication No. 2010/0028512,which includes 100% bio-based virgin material. With each of the firsttwo examples, there is no contemplation of any PCR content.

Example 3 is an example of an article having both bio-based material andPCR. In that example, 25% content by weight of the article is bio-MEGbased PET (or “up to 30% bio-based content PET”), and 75% content byweight is PCR PET. The PCR content in this example has no bio-basedprovenance and may be considered standard, commodity or virgin PCR.

Example 4 involves aspects of the instant teachings, and envisions acontainer a bio-based plastic container that includes recycled bio-basedmaterials. For some embodiments that involve the inclusion of recycledbio-based materials an element (e.g., a dye) may be included to mask orinhibit characteristics (such as “haze”) that might be associated withthe use of recycled content in connection with the article.

Example 6 involves aspects of the instant teachings, and envision abio-based container that includes recycled bio-based materials. Forexample, a manufacturer's objective may be to provide an article thatemploys PCR content while maintaining the level of bio-based contentthat it might commonly employ when using virgin material. For exampleand without limitation, with Example 6 an article may have about 90% byweight virgin bio-based content. The particular bio-based content is “upto 30% bio-based,” such as PET having its ethylene glycol (EG) componentcompletely derived from bio-based sources. The example article would beable to maintain its 30% bio-based content despite adding PCR materialsince the manufacturer is able to source PCR material havingsubstantially similar (or even equal or nearly equal) bio-based contentas the virgin component. Maintaining such a bio-based equilibrium can bea significant objective or goal for some applications. One way, forexample, for achieving a bio-based equilibrium is utilizing both virgincontent and PCR content, even at different amounts by weight, with thevirgin and PCR content each having substantially similar bio-basedpercentages. It is noted that the foregoing principles may be applied toarticles having a wide range of bio-content percentages, including thosewith bio-based percentages ranging from above 0% to about 100%.

For some embodiments of a bio-based plastic article including PCRbio-based materials, the PCR bio-based material content may be up to100% by weight of the un-filled container. However, a preferredembodiment may comprise PCR bio-based material at between about 1% andabout 50% by weight and virgin material at between about 50% and about99% by weight. More preferably, the PCR bio-based material would bepresent at from about 1% to about 20%, and the virgin material would bepresent from about 80% to about 99%. The virgin material may optionallybe bio-based. Of the recycled bio-based material content, it maycomprise, without limitation, one or more of the following: “up to 30%bio-based” PCR resin, 100% bio-based PCR resin, or a custom blend of PCRbio-based resins.

Embodiments of a PET bio-based container (with or without recycledbio-based materials) may, for example and without limitation, beprovided in a monolayer configuration. Embodiments of bio-basedcontainers (with or without recycled bio-based materials) may, forexample and without limitation, be provided in a multi-layerconfiguration.

The foregoing descriptions of specific embodiments of the presentinvention have been presented for purposes of illustration anddescription. They are not intended to be exhaustive or to limit theinvention to the precise forms disclosed, and various modifications andvariations are possible in light of the above teaching. The embodimentswere chosen and described in order to explain the principles of theinvention and its practical application, to thereby enable othersskilled in the art to utilize the invention and various embodiments withvarious modifications as are suited to the particular use contemplated.It is intended that the scope of the invention be defined by the claimsand their equivalents.

What is claimed is:
 1. A bio-based plastic container comprising recycledbio-based material, the bio-based plastic container comprising betweenabout 1% and about 50% by weight of recycled bio-based material; whereinthe bio-based plastic container is comprised of both recycled bio-basedpolymer and a petrol-based polymer; wherein the bio-based plasticcontainer includes an identifier; and wherein the identifier representsor discloses information that distinguishes between content of recycledbio-based polymer and content of petrol-based polymer comprising thebio-based plastic container.
 2. The bio-based plastic container of claim1, wherein the identifier represents or discloses a bio-based materialpercentage.
 3. The bio-based plastic container of claim 1, wherein theidentifier includes one or more additives, and the one or more additivesdistinguishing the bio-based plastic container from a petrol-basedcontainer.
 4. The bio-based plastic container of claim 1, wherein theidentifier comprises a colorant or dye.
 5. The bio-based plasticcontainer of claim 4, wherein the colorant or dye is included in resinforming the bio-based plastic container.
 6. The bio-based plasticcontainer of claim 1, wherein the identifier is not visible/perceptibleto a human eye without equipment.
 7. The bio-based plastic container ofclaim 1, wherein the identifier represents or discloses a percentage ofthe bio-based plastic container that is comprised of a bio-basedmaterial.
 8. The bio-based plastic container of claim 1, including adistinguishing or visible mark that designates the plastic container asbio-based.
 9. The bio-based plastic container of claim 1, wherein theidentifier comprises a marker.
 10. The bio-based plastic container ofclaim 9, wherein the marker includes one of more of the following: UVdye, colorant, chemical trace, organic additive, tint.
 11. The bio-basedplastic container of claim 9, wherein the marker is a compound added toa resin forming the bio-based plastic container.
 12. The bio-basedplastic container of claim 1, wherein the identifier includes a tracer.13. The bio-based plastic container of claim 12, wherein the tracerdistinguishes resin produced by a manufacturer from similar resinsproduced by others.
 14. The bio-based plastic container of claim 12,wherein the tracer is at a level in single parts per billion or less.15. The bio-based plastic container of claim 12, wherein the tracer isadded during a melt polymerization phase or a solid state polymerizationstage.
 16. The bio-based plastic container of claim 12, wherein thetracer identifies bio-based containers for recovery within a recyclingprocess.
 17. The bio-based plastic container of claim 1, wherein therecycled bio-based material includes PCR bio-based material.
 18. Thebio-based plastic container of claim 17, wherein the PCR bio-basedmaterial is up to 100% of the total weight of the bio-based plasticcontainer in an un-filled condition.
 19. The bio-based plastic containerof claim 17, wherein the PCR bio-based material comprises up to 30%bio-based PCR resin.
 20. The bio-based plastic container of claim 17,wherein the PCR bio-based material comprises between about 1% and about20% of the total weight of the bio-based plastic container in anun-filled condition.
 21. The bio-based plastic container of claim 17,wherein the PCR bio-based material comprises between about 1% and about20% of the total weight of the bio-based plastic container in anun-filled condition, a virgin material comprises about 80% to about 99%of the total weight of the container, and the virgin material isbio-based.
 22. The bio-based plastic container of claim 17, wherein therecycled bio-based material comprises one or more of the following: upto 30% bio-based PCR resin, 100% bio-based PCR resin, and/or a customblend of PCR bio-based resins.
 23. A system for reclaiming bio-basedplastic material, comprising: an apparatus or device configured toobtain or determine a bio-based material content associated with aplastic container; and an apparatus or device configured to sort theplastic container based upon the bio-based material content of theplastic container.
 24. The system of claim 23, wherein the plasticcontainer includes post-consumer bio-based material.